Drilling tool and method for producing port seals

ABSTRACT

The present invention provides a new drilling tool useful in machining hydraulic port seals for fluid power ports. The drilling tool drills the port hole to size in a solid material for the minor thread diameter in combination with forming the port in a single operation. The drilling tool has a tool holder having a rotational axis, a first drilling insert having cutting surfaces on a first side and a mounting surface on a second side, at least one second drilling insert having a predetermined cutting surface portion and a mounting portion which is mounted on the holder at a location from the rotational axis of the holder. The at least one second drilling insert has first and second portions which engage and machine a work piece in a drilling operation to form a spot face and a seal form.

This application claims the benefit of U.S. Provisional Patent Application Ser. No. 60/404,091 filed Aug. 16, 2002, and incorporated by reference herein. The invention is directed to a drilling tool for use in production of predetermined hole geometries. More particularly, the invention is directed to a drilling tool useful in machining hydraulic port seals for fluid power ports.

TECHNICAL FIELD Background of the Invention

In typical drilling operations, a drilling tool is designed to configure a predetermined hole profile in a machining operation to facilitate particular applications. It is desired to form a predetermined configuration hole profile without secondary machining operations, and in a quick and efficient manner. The cutting or boring action of a drilling tool may be performed by an elongated, substantially cylindrical drilling tool, such as a combination of a tool holder and a drill insert attached thereto. Typically the cutting insert engages the material to be cut upon relative rotation between the tool and work piece. The use of cutting inserts allows for quick changing of the insert upon wear of the cutting surfaces, instead of replacement of the entire tool. Further, the use of cutting inserts allows one tool to be used for varying boring applications by changing the insert configuration instead of the entire drilling assembly.

In known port contour cutters for the above application, the tools are typically made of solid HSS, braised tipped carbide, indexable carbide inserts or replaceable carbide inserts. In known configurations and prior methods of forming port holes have generally required multiple machining operations. For example, the manufacturer of a port hole has typically required a first step of spot drilling the port hole, thereafter pre-drilling the port hole and a third operation to size the minor thread diameter and form the port hole. This operation typically encompassed the following after pre-drilling: (1) ream and then use a form tool with a pilot for the port form, and (2) ream and port form combination tool, with the reamer used as a pilot. It would therefore be desirable to provide a drilling tool and method which will drill the port hole to size in a solid material for the minor thread diameter in combination with forming the port in a single operation. Further, in known configurations, the tools are radially non-adjustable, and axial adjustment can only be accomplished by adjusting the stick-out of the cutting tool in the holder. It would be an advantage to provide a port contour cutter which allows radial and axial adjustment in a simple and effective manner.

SUMMARY OF THE INVENTION

Based upon the foregoing, the present invention provides a novel drilling tool and method which overcomes limitations found in the prior art, and enables the efficient and effective production of port holes. It is therefore an object of the invention to provide a drilling tool comprising a port contour cutter which allows machining of a port hole to produce the minor thread diameter and the port form in a single operation. In general, the drilling tool according to the invention comprises a tool holder having a rotational axis, with which drilling inserts are selectively mounted. A first drilling insert having cutting surfaces on a first side, and a mounting surface on a second side thereof, is selectively mounted along the rotational axis of the tool holder. At least one second drilling insert having a predetermined cutting surface portion and a mounting portion is selectively mounted with the holder at a predetermined outboard location from the rotational axis of the holder. The at least one second drilling insert is non-indexable. The invention also provides a method of drilling a port hole configuration to produce the minor thread diameter and the port form in a single operation.

These and other objects and advantages of the invention will become apparent upon a reading of the description of an embodiment thereof, in conjunction with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic representation of a port hole configuration having a connector coupled therewith, such as a hydraulic port seal connection as found in the prior art.

FIG. 2 shows a side elevational view of an embodiment of the drilling tool according to the invention.

FIG. 3 shows a side elevation of the tool as shown in FIG. 2, rotated by 90°.

FIG. 4 is a top view of the tool as shown in FIG. 2.

FIG. 5 is a partial exploded view showing the tool holder and drilling inserts according to an embodiment of the invention.

FIG. 6 is a side elevation view of a port form insert according to an embodiment of the invention.

FIG. 7 is a top view of the port form insert as shown in FIG. 6.

FIG. 8 is a side view of the port form insert as shown in FIG. 6.

FIG. 9 is a perspective view of the port form insert as shown in FIG. 6.

FIG. 10 is an elevational view of an alternate embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

In one particular type of application, for a fluid port seal which is threadably engaged with a hydraulic or other fluid line and sealed by means of an o-ring, requires a particular type of hole profile. As seen in FIG. 1, the shape of a fluid power port, such as a hydraulic porthole 10, uses a truncated or tapered hole 12 leading into a threaded hole 14. A hydraulic connector to the porthole 16 is positioned above the port taper 12 as shown at 18, and includes a flange 17 which bottoms out against the face of the work piece. Below the flange 17 are typically straight threads (not shown) formed on the connector, which engage the cylindrical, threaded hole at 14. To provide a seal for the connector 16, an o-ring 20 is provided in association with an undercut 22 formed in the connector, which mates with the tapered portion of the hole 12, providing a seal seat for properly sealing the port. Different threads may be used in association with the connector 16, and the configuration of the machined tapered hole remains substantially consistent except for the provision of alternative threading configurations. For example, in practice, both imperial straight threads and metric straight threads may be used with a hydraulic port, with other dimensions typically provided in metric dimensions. To identify a metric thread porthole, the porthole may be produced with an identification ridge 24, allowing simple and effective identification that the port thread is metric.

Turning now to an embodiment of the present invention, FIGS. 2-4 illustrate a drill tool assembly 50 for producing predetermined configuration holes in a work piece. Drill tool assembly 50 comprises a holder 52, having a shank portion 54 and a head portion 56 associated therewith. Within the head portion 56, a mounting slot 58 is formed at a central portion of the holder 52 to allow selective mounting of a first drilling insert 60 along the rotational axis of the holder 52. The slot 58 may be configured to have a bottom wall positioned in substantially perpendicular orientation relative to the rotational axis of the holder 52, and may include a locating boss or pin (not shown), positioned precisely with respect to the rotational axis, for proper positioning of insert 60 along the rotational axis. The configuration of the tool holder 52 with respect to the mounting slot 58 may be generally similar to the tool holder and drill insert configuration such as produced by Allied Machine & Engineering Company, such as in the T-A™ drilling system. The drilling insert 60 is therefore precisely positioned with respect to the holder 50, to perform the desired drilling function in conjunction therewith.

The holder 52 in this embodiment is shown to have a straight round shank leading to a ground qualified shoulder 55. The shank may be manufactured without a locking flat to be usable with hydraulic chucks, heat shrink holders or collet chucks, to gain higher dimensional accuracy, concentricity and balance. Alternatively a locking flat may be formed in the holder 52. Alternative configurations of holder 52 are contemplated, such as with alternative shank configurations to adapt to a particular machine spindle, such as CAT, BT, HSK, KM, ABS or the like. Precision holders may have a qualified length to the face, which in turn requires a ground shoulder on the cutting tool that is qualified, but again other configurations are contemplated.

The insert 60 is securely mounted in association with head portion 56 by means of clamping arms 62 having apertures 63, which can accommodate screws or other fasteners to secure the drill insert 60, having corresponding apertures 64. Each of the clamp arms 62 may also include a coolant or lubrication vent 66, which allows the application and flow of a coolant or lubricant adjacent the cutting surfaces of the drill insert 60, to facilitate the drilling operation. The vents 66 allow a liquid or air coolant/lubricant to be introduced to the hole bottom through the tool holder body 52. The liquid or air coolant helps to transport machined cuttings from the hole bottom, as well as cool the drill inserts at and from the bottom of the machined hole. Alternatively, an external coolant supply may also be used if desired. The clamp arms 62 may also include angled or curved surfaces 68, which facilitate chip removal via chip evacuating grooves 70 on each side of the holder 52.

In the embodiment of the invention, there is also provided at least one second drill insert 80 coupled to the drill holder 52 at a predetermined position. In the embodiment as shown in the figures, at least one second insert 80 comprises a pair of such inserts mounted on opposing sides of the holder 52. The insert 80 includes a mounting aperture 82 corresponding to a mounting aperture 84 formed in the holder 52. The holder 52 is formed with insert seats 86, which precisely mount the inserts 80 in relation to the rotational axis of holder 52, in a non-indexable manner. This can be seen in FIG. 2, and similar to the mounting configuration of insert 60, the mounting holes 82 formed in inserts 80 may be of tapered configuration, and slightly offset from the apertures 84 formed in the tool holder, to selectively bias the insert against the insert seat 86, for positive and precise mounting thereof. The connection of the inserts 60 and 80 and other aspects of the tool holder 52, may be generally similar to tool holder and insert mounting configurations as used in the Allied Machine & Engineering tools mentioned previously, or such as described in co-owned U.S. Pat. No. 5,957,635, which is hereby incorporated by reference herein. The inserts 60 and 80 may be made of a sintered metallic hard material such as carbide, cermet, ceramic, monocrystalline and polycrystalline diamond, or boron nitride as examples. Alternatively, high speed steel or other materials may be used.

The various inserts 60 and 80 in relation to the tool holder 52 are shown in FIG. 5. Using a single-sided inserts 60 and 80 in conjunction with tool holder 52, allows each of the inserts to be selectively removed and replaced in a simple and effective manner upon wear of the inserts during a drilling operation. The drill insert 60 performs a primary drilling operation, and may comprise the T-A™ drill insert produced by the Allied Machine & Engineering Company. The drill insert 60 in conjunction with tool holder 52, will produce the minor diameter for the thread size required for production of a hydraulic port seal or other connection for fluid power ports, or for other possible applications. The depth for this minor diameter portion of the machined work piece is generally dictated by the port specification, but can also be changed to suit the application and produced as a special tool for a desired depth.

In the drilling tool 50, a port form portion comprises the at least one second insert 80, or as shown in this embodiment of the invention, two opposing form inserts 80 mounted on tool holder 52. Using two effective/opposing form inserts 80 for the task of producing the port form in a machined work piece in conjunction with the minor diameter machine hole formed by insert 60, may enhance formation of both the minor thread diameter and port form in a single operation. In this way, the present invention provides a drilling system which does not require pre-drilling, and will therefore save set up in production time as well as tool cost associated with a pre-drilling operation. The replaceable inserts associated with the drilling system 50 will therefore not require braised carbide re-tipping or regrinding, which can result in size loss or the need to reset tool parameters. The use of precisely machined inserts 60 and 80 allow repeatability in the machining operation, and allow the user to select drill speeds and feeds according to coated carbide or coated HSS drill recommendations as an example. As the machining operation of the minor thread diameter and port form is performed at the same time, drill speeds can be set to the drill diameter and not a spot faced diameter, as a spot face operation performed by the insert 60 is of short duration and does not produce enough heat to damage the port form insert spot face area. By coating inserts 60 and 80 with materials, such as titanium aluminum nitride (TiAlN), diamond or the like, the tool will have a longer life, and replacement of the insert 60 and 80 is simple and efficient. It has also been found that the combination of the drill insert 60 with the at least one second insert 80 provides a drill system which is stabilized during the drilling operation, particularly when the port form inserts 80 are engaged in the work piece. Proper stabilization provides excellent surface finish and accuracy in the machined work piece. The drilling tool system also allows the drilling operation to be performed without dwell, so that the spot face area cannot start scraping to produce chatter or bad surface finish in the machined hole. In the drilling operation, the holder 52 can be made to rotate a sufficient degree to clean up the spot face surface prior to retraction of the holder 52.

In the drilling system 50, the provision of a pair of second inserts 80 allows the feed rate per insert to be the same as the feed rate per flute for the drill system 50, such that the feed rate per edge equals the feed rate per revolution divided by two. As shown in FIG. 5, the insert seats 86 are located relative to the drill insert 60 mounting location in a predetermined manner. In the embodiment shown, the seat 86 location is rotated approximately 15° below the drill insert 60 location. This will enhance tool life of the drilling system 50 in that chip flow coming from the drill insert 60 will not hit the port form inserts 80, which could cause possible damage to the cutting surfaces of inserts 80. Further, the chip flow coming from the inserts 80 will not interfere with the chip flow from the drill insert 60, ensuring good chip evacuation from both inserts 60 and 80. In a preferred form, the angle of rotation, such as approximately 15°, is in-line with the axis of the tool, which opens the chip gullet and prevents clogging of the chips that could choke the drill system 50. Also, the rotation of the inserts may offset the multi-directional tool and cutting forces, decreasing harmonic vibrations and drill chatter. Although the rotation of the inserts 80 approximately 15° has been found to work effectively, the inserts may also be positioned without any rotation or at other rotation angles, such as between 5°-25° for example.

Turning to FIGS. 6-9, an embodiment of the replaceable insert 80 is shown in more detail. As seen in these FIGS., the insert 80 is generally of rectangular plate form, allowing simple and cost effective manufacture of the inserts 80, along with simple and cost effective formation of the pockets or seating surfaces 86 in the holder 52. These aspects are similar for insert 60, wherein each of the insert 60 and 80 allow precise repeatability of inserts having substantially identical characteristics. The inserts 60 and 80 are also replaceable, and non-indexable, to avoid problems of indexable inserts known in the prior art. For example, indexable inserts may have one side manufactured wrong, making the entire insert scrap. Alternatively, after a first side of an indexable insert is used, it can be easily mislocated or be rendered unusable due to edge build up, chipped edges and/or broken edges caused by the initial drilling operation. Providing simply manufactured inserts 60 and 80, which are non-indexable, but easily replaceable, allows for a more cost effective operation than in the use of indexable inserts.

In the present invention, it may be desirable to hone a sharp edge formed on the insert 80, which could result in chipping, such as by dry bead blast honing or other suitable method. The hone may aid the adherence of a coating and prolonged tool life, as well as void chipping under certain applications. At the same time, certain applications may require a sharp edge, and such a sharp edge may be maintained in an un-honed and uncoated condition if desired. It may be desirable in an application in which honing is helpful, to provide a heavier hone at the spot facing edge and a lighter hone at the seal angle edge of the insert 80, as will be hereinafter described. The degree of honing may be compatible with the actual chip thickness produced by the cutting surfaces of insert 80.

The insert 80 in general has a configuration which will be described relative to the minor diameter 90. At a top portion of the insert 80 adjacent the minor diameter surface 90, a 45° chamfer 92 may be configured to lead into the seal angle cutting surface 94, which typically may be a 12-15° angled surface, but may be of another desired angle. A chamfered surface 93 may be provided along the rear seating surface of the insert 80 to correspond to the seating surfaces machined in the holder 52. The seal angle 94 terminates with a small corner radius at 96 leading to the spot face 98. The spot face 98 depth from the top of the insert is predetermined based upon port specifications or the like, and may be adapted for any particular application. At the outside of the spot face 98, a small corner radius 100 leads to a second angle 102 that shapes the outside wall of the spot face diameter at 104. The outside edge 104 of the insert 80 may be formed as a wiper edge that produces the inner diameter of the spot face, and may be configured to have a slight angle between 0 and 5°, which will allow a slight amount of material to be shaved from the machined surface as the tool cuts deeper so as to slightly enlarge the inner diameter and reduce burr in the finished hole. Other angles for the wiper edge 104 are contemplated.

The insert 80 may be referred to as a “full form” insert, or a “wrap around” insert which desirably has the capability to cut around corners and chamfers and blend all surfaces. In this way, a machined form is produced without burrs, witness marks, sharp edges or other surface defects. In the embodiment as shown in FIGS. 6-9, there is noted an optional notch 106 which may be formed in the insert 80 to produce the identification ridge 24 (as seen in FIG. 1), to identify the port as metric.

In the manufacture of insert 80, by taking advantage of the port seal diameter desired for a particular application, and the spot face diameter tolerances, a single port form may accommodate several port sizes. The inserts 80 can be made from blanks, such that a single blank may accommodate more than one insert. The insert 80 may be coated by known suitable methods, with a desired coating based upon a particular application for the tool 50. As an example, an application in aluminum may desirably use a diamond film coating on the inserts 60 and 80, or other coating materials, such as titanium aluminum nitride, may be used.

The inserts 80 generally may not need additional coolant holes, as the cutting action performed thereby is of relatively short duration, and at the end of the drilling operation. Residual coolant from the hole being drilled, introduced by coolant holes 66 or an external coolant supply, may be sufficient for cooling the cutting surfaces of the inserts 80. If a through hole is provided, an outside source of coolant may be required. Although the use of coolant holes to supply coolant directly to the area of inserts 80 may not be necessary for certain applications, such additional coolant holes (shown in ghost at 67) could be provided if desired or needed for a particular application.

With the configuration of the inserts 80, several cutting surfaces are formed to produce desired machine surfaces in a work piece. The insert 80 will have two different areas producing two different types of material chips, from the seal form surface 94 as well as spot face surface 98. The seal form area cutting edge will enter the hole at an angle, such as between 12-15°, adjacent to the centerline. Due to this acute angle, the theoretical chip thickness will only be approximately 10-15% of the actual feed rate and the actual chip thickness not appreciably increased. In the spot face area, the cutting edge will approach the material at approximately 90° to the centerline and the theoretical chip thickness will be approximately 100%. In the embodiment shown in FIG. 2, as an example, the inserts 80 are placed above center in the holder 52 to slightly increase the cutting pressures and reduce and/or eliminate chatter and vibration. As an alternative embodiment, as shown in FIG. 10, and to provide radial and axial adjustment in the drilling system 50, the inserts 80 may be located on an independent cartridge 110 formed to be mountable with the holder 52. A plurality of such cartridges 110 allowing radial and axial adjustment of the relative positions of inserts 80 relative to the holder 52 and cutting insert 60. Cartridges 110 may be nested against three sides for proper positioning relative to the holder and other tool components, and fastened with a suitable fastener such as a screw. In this manner, the tool 50 may be fine tuned, even when mounted within a spindle for operation, in the case of spindle run-out or other problems a turning machine may have. Adjustment of the cartridges may be performed via shims, set screws or the like, to facilitate repositioning.

Although the present invention has been described above in detail relative to a particular embodiment thereof, the same is by way of illustration and example only, and is not to be taken as a limitation on the present invention. Accordingly, the scope and content of the present invention are to be defined only by the terms of the appended claims. 

1. A drilling tool comprising: a tool holder having a first end, a second end, and an intermediate portion between the first end and the second end, and a rotational axis, the first end comprising a holder slot having a bottom seating surface and at least one attachment arm positioned on each side of the holder slot, the second end comprising a shank portion, and the intermediate portion comprises at least one insert attachment seat portion; a first drilling insert having cutting surfaces formed transverse to each other on a first end, and a mounting surface on a second end thereof, the first drill insert being selectively mounted along the rotational axis of the holder within the holder slot of the first end of the holder; and at least one second drilling insert attachable to the insert seat attachment portion of the intermediate portion of the holder, the second drilling insert comprising a cutting face side opposite a register face side, and a plurality of side surfaces therebetween, the plurality of side surfaces comprising a first resister side surface formed generally perpendicular to the rotational axis of the tool forming a bottom seating surface of the second insert, a second register side surface formed generally parallel to the rotational axis of the tool forming a radial inward seating surface of the second insert, a first cutting edge generally parallel to the rotational axis of the tool for forming the diameter of a counterbore, a second cutting edge generally perpendicular to the first cutting edge for forming a bottom surface or spotface of the counterbore, a third cutting edge formed transverse to the rotational axis of the cutting tool for forming a seal angle, and a fourth cutting edge formed transverse to the rotational axis of the cutting tool for forming a chamfer, wherein the first register side surface of the second insert extends radially from the second resister side surface to the first cutting edge and the second register side surface extends axially from the first resister side surface to at least beyond the third cutting edge, wherein the first and second drilling inserts are replaceable and non-indexable.
 2. The drill tool of claim 1 wherein said drilling inserts are made of a sintered metallic hard material.
 3. The drill tool of claim 2 wherein the sintered metallic hard material is selected from the group consisting of a carbide, a cermet, a monocrystalline diamond, a polycrystalline diamond, a boron nitride, and combinations thereof.
 4. A drilling tool comprising: a tool holder having a first end, a second end, and an intermediate portion between the first end and the second end and a rotational axis therethrough, the first end comprising a holder slot having a bottom seating surface and at least one attachment arm positioned on each side of the holder slot, the second end comprising a shank portion, and the intermediate portion comprising a plurality of insert attachment seat portions; a first drilling insert having cutting surfaces formed transverse to each other on a first end, and a mounting surface on a second end thereof, the first drill insert being selectively mounted along the rotational axis of the holder within the holder slot of the first end of the holder; and a plurality of secondary drilling inserts attachable to the plurality of insert seat attachment portions of the intermediate portion of the holder such that each secondary drilling insert comprises at least four cutting edges adapted to form a port seal, a first register surface formed generally parallel to the rotational axis of the tool and a second register surface formed generally perpendicular to the rotational axis of the tool, and a third register surface formed generally perpendicular to the first register surface and the second register surface, the first register surface extending generally the entire axial height of the secondary insert and the second register surface extending generally the entire radial width of the secondary insert; wherein the first and secondary inserts are replaceable and non-indexable.
 5. The drill tool of claim 4, wherein said plurality of secondary inserts are radially offset from the first insert.
 6. The drill tool of claim 1 wherein said at least one second drilling insert is radially offset at a radial angle from said first drilling insert.
 7. The drill tool of claim 4, wherein said plurality of secondary inserts are attached to the holder in positions equally spaced radially from each other.
 8. The drill tool of claim 6, wherein a line through the second cutting edge of the at least one second insert does not extend radially through the rotational axis of the tool.
 9. The drill tool of claim 6, wherein the radial angle is between 5°-25°.
 10. The drill tool of claim 1 further comprising a radius cutting portion adjacent the radial outward end of the second cutting edge leading to an angled cutting portion transverse to the first cutting edge of the at least one second cutting insert.
 11. The drill tool of claim 1 wherein the first cutting edge of the at least one second insert further comprises a notch for forming an identification ridge to identify said port.
 12. The drill tool of claim 1 wherein the at least one second insert is coated.
 13. The drill tool of claim 12 wherein the at least one second insert is coated with titanium aluminum nitride, diamond, titanium carbo-nitride, aluminum chromium nitride, zirconium nitride, cubic boron nitride, or combinations thereof.
 14. The drill tool of claim 1 further comprising at least one coolant hole formed in the holder to direct coolant toward the cutting edges of the at least one second insert.
 15. The drill tool of claim 1 wherein said at least one second insert is located on an independent cartridge attachable to the intermediate portion of the holder, wherein a plurality of said cartridges are adapted to permit radial and axial adjustment of said at least one second insert position relative to said holder and said first cutting insert. 